Stud male-originating chemosignals: A luteotrophic agent.

The chemosignals from mating male are found to be responsible for protecting his coital partner against pregnancy failure induced by strange male or food-deprivation. The stud male pheromone not only provides luteotrophic support in female of vulnerable condition but also exerts luteotrophic effect in pregnancy-blocked females by inducing pseudopregnancy. The luteotrophic stimulus rendered by stud male to prevent pregnancy failure is mediated through the main olfactory system, and not through the accessory olfactory system, since the accessory olfactory system is primarily involved in perceiving the luteolytic stimulus produced from strange male for causing pregnancy failure. It has been shown that pericopulatory period seems to be crucial in females in the formation of stud male chemosignals, and the olfactory luteotrophic memory of stud male is further proved to be a short-term one. The precise mechanism involved in accessing and retaining the stud male chemical cues is unclear. In this brief review an attempt has been made to bring out the luteotrophic process of stud male chemosignals, the olfactory pathway and critical period to access the signals. The possible neural mechanism and neural chemistry underlying the formation and recognition of mating male chemical cues are also highlighted.

Postnatal development of the female rabbit vomerosensory epithelium: a light and electron microscopic study

The vomeronasal organ [VNO] is an essential organ with regard to its recognition as a receptor of nonvolatile substances known as pheromones and its link with mammalian reproduction. The postnatal development of the vomerosensory epithelium of the VNO of female white rabbits has been investigated in this study. Four age groups [newborn, 1 week, 2 weeks, and 1 month] were studied using light and electron microscopic techniques. Three basic cell types have been distinguished in the rabbit vomerosensory epithelium: supporting cells, sensory neuronal cells, and basal cells. The supporting cells showed signs of maturation as enlargement and branching of the microvilli and difficulty of identification of centrioles in the apical parts of the cells. The sensory cells showed different stages of maturity; some changes have been found in the morphology and development of the cell organelles. There was decrease in the number of ribosomes and increase in the number of arborizations of their microvilli. The basal cells were present more at birth and decreased as the rabbits grew. There was maturation of the histological structure of the sensory epithelium of the VNO of female rabbits, which indicated the presence of great signs of functional activity at birth that continued during the first month of age to acquire mature functional capability

Identification of 2u-globulin and bound volatiles in the Indian common house rat (Rattus rattus)

The 2u-globulin (2u) is a pheromone carrier urinary protein believed to be relevant for sexual communication among rats and is characterized in laboratory rats. In the present study 17 kDa protein and the bound pheromones were characterized in a population of wild-type Indian common house rat (Rattus rattus). The protein was purified by two runs of Sephadex G-50 chromatography and analyzed with SDS-PAGE with MALDI-TOF/MS. The results of MASCOT search identified the protein as an 2u and suggested a role for binding pheromones. To confirm the protein bound volatiles, purified 2u was extracted with dichloromethane and volatile molecules were detected using of gas chromatography linked to mass spectrometry (GC-MS). 1-Chlorodecane was detected as the predominant compound and 2-methyl-N-phenyl-2-propenamide, hexadecane and 2,6,11-trimethyl decane as the minor compounds. The simple method of protein purification and the identification of bound volatiles may help in designing efficient pheromone-based rat traps.

Assessment of pheromone response in biofilm forming clinical isolates of high level gentamicin resistant Enterococcus faecalis.

Twenty five clinical isolates of high level gentamicin resistant Enterococcus faecalis were tested for their biofilm formation and pheromone responsiveness. The biofilm assay was carried out using microtiter plate method. Two isolates out of the 25 (8%) were high biofilm formers and 19 (76%) and four (16%) isolates were moderate and weak biofilm formers respectively. All the isolates responded to pheromones of E. faecalis FA2-2 strain. On addition of pheromone producing E. faecalis FA2-2 strain to these isolates, seven of 19 (37%) moderate biofilm formers developed into high biofilm formers. Similarly one of the 4 (25%) weak biofilm formers developed into high level biofilm former. Twelve (48%) of the 25 isolates were transconjugated by cross streak method using gentamicin as selective marker. This proves that the genetic factor for gentamicin resistance is present in the pheromone responsive plasmid. Among these twelve transaconjugants, seven isolates and one isolate were high biofilm formers on addition of E. faecalis FA2-2 and prior to its addition respectively. Out of the total 25 isolates, eight transconjugants for gentamicin resistance could turn to high biofilm formers on addition of the pheromone producing strain. All the isolates were resistant to more than two antibiotics tested. All the isolates were sensitive to vancomycin. The results indicate the significance of this nosocomial pathogen in biofilm formation and the role of pheromone responding clinical isolates of E. faecalis in spread of multidrug resistance genes.

Comparative study of the cuticular hydrocarbon in queens, workers and males of Ectatomma vizottoi (Hymenoptera, Formicidae) by Fourier transform-infrared photoacoustic spectroscopy

Fourier transform-infrared photoacoustic spectroscopy was applied for the first time, to our knowledge, to distinguish different castes of an ant species. The method was applied directly to the abdomen of queens, workers and males of Ectatomma vizottoi ants, without any special sample preparation. The absorption bands of secondary amide and hydrocarbons were identified; using these as variables in a canonical discriminant analysis we found significant differences between the castes. Queens have a greater hydrocarbon content than do workers and males, which is related to their function in the colony. This technique can be used to analyze and distinguish small chemical differences in biological systems, even in opaque samples.

Gene networks as a tool to understand transcriptional regulation

Gene regulatory networks, or simply gene networks (GNs), have shown to be a promising approach that the bioinformatics community has been developing for studying regulatory mechanisms in biological systems. GNs are built from the genome-wide high-throughput gene expression data that are often available from DNA microarray experiments. Conceptually, GNs are (un)directed graphs, where the nodes correspond to the genes and a link between a pair of genes denotes a regulatory interaction that occurs at transcriptional level. In the present study, we had two objectives: 1) to develop a framework for GN reconstruction based on a Bayesian network model that captures direct interactions between genes through nonparametric regression with B-splines, and 2) to demonstrate the potential of GNs in the analysis of expression data of a real biological system, the yeast pheromone response pathway. Our framework also included a number of search schemes to learn the network. We present an intuitive notion of GN theory as well as the detailed mathematical foundations of the model. A comprehensive analysis of the consistency of the model when tested with biological data was done through the analysis of the GNs inferred for the yeast pheromone pathway. Our results agree fairly well with what was expected based on the literature, and we developed some hypotheses about this system. Using this analysis, we intended to provide a guide on how GNs can be effectively used to study transcriptional regulation. We also discussed the limitations of GNs and the future direction of network analysis for genomic data. The software is available upon request.

Cell signaling pathways in Paracoccidioides brasiliensis: inferred from comparisons with other fungi

The human fungal pathogen Paracoccidioides brasiliensis is an ascomycete that displays a temperature-dependent dimorphic transition, appearing as a mycelium at 22 degrees C and as a yeast at 37 degrees C, this latter being the virulent form. We report on the in silico search made of the P. brasiliensis transcriptome-expressed sequence tag database for components of signaling pathways previously known to be involved in morphogenesis and virulence in other species of fungi, including Saccharomyces cerevisiae, Cryptococcus neoformans, Candida albicans, and Aspergillus fumigatus. Using this approach, it was possible to identify several protein cascades in P. brasiliensis, such as i) mitogen-activated protein kinase signaling for cell integrity, cell wall construction, pheromone/mating, and osmo-regulation, ii) the cAMP/PKA system, which regulates fungal development and virulence, iii) the Ras protein, which allows cross-talking between cascades, iv) calcium-calmodulin-calcineurin, which controls cell survival under oxidative stress, high temperature, and membrane/cell wall perturbation, and v) the target of rapamycin pathway, controlling cell growth and proliferation. The ways in which P. brasiliensis responds to the environment and modulates the expression of genes required for its survival and virulence can be inferred through comparison with other fungi for which this type of data is already available.

La glándula de Harder: un transductor neuroinmunoendrocrino / The Harderian gland: neuroinmunoendrocrine transductor

La glándula de Harder es una glándula túbulo-alveolar localizada en la parte posterior de la órbita ocular de animales que poseen membrana nictitante. En estos mamiferos la glándula contiene una gran cantidad de lípidos. La glándula de Harder de roedores contiene un pigmento café rojizo, el cual ha sido identificado como porfirina. Las funciones de la glándula de Harder son; síntesis y liberación de ferhormonas, fotoprotección y termorregulación, osmoprotección y se le ha propuesto además un papel inmunoendocrino